third industrial revolution is often referred to as either the computer revolution or the digital revolution.
currently experiencing a fourth industrial revolution, which began early in the twenty-first century.
the rise of machine learning and artificial intelligence.
material science to nanotechnology, energy to biology.
it merges these fields and connects them across digital, physical and biological platforms.
the modern world is more interconnected and richer in technology than ever before.
This change is driven by digitization and automation of production.
this revolution is defined by speed, but also by unprecedented returns to scale that allow businesses to produce the same or greater value with relatively fewer employment-associated costs. This change is driven by digitization and automation of production.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people. That’s just over a tenth of the workforce that the Detroit firms had in 1990.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The fourth industrial revolution has enabled a series of incredible new physical possibilities.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The
autonomous vehicles, 3D printing, advanced robotics and new materials.
because of advanced sensor technology, drones can now navigate much more effectively in response to the environment and therefore can be used for a number of new tasks, like dropping medicine into war zones
second physical trend of this industrial revolution is 3D printing, or, as it’s sometimes called, additive manufacturing.
3D printing is already being used in fields as diverse as medicine and energy production, producing everything from micro medical implants to massive wind turbines.
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat. But not every trend in the fourth
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat.
physical innovations are a major aspect of the fourth industrial revolution, others are purely digital.
IoT is a core concept that brings together physical and digital applications.
packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment,
Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
The current industrial revolution encompasses transformative digital and biological trends. While physical innovations are a major aspect of the fourth industrial revolution, others are purely digital. One of these is known as the internet of things, or IoT. The IoT is a core concept that brings together physical and digital applications. It describes a network between physical devices – be they smartphones or home appliances – and the people who use them. Constructing such a network is possible thanks to advances in technologies like transmitters and sensors. For example, these days packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment, enabling us to follow their progress as they make their way to us. Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
biological trends and innovations around things like genetics. Genetic engineering, in particular,
biological trends and innovations around things like genetics. Genetic engineering, in particular, will have a tremendous impact on humanity.
science may soon be capable of precision medicine. That is, scientists could do things like decode the genetic composition of a tumor and offer a treatment that’s tailored to that specific case of cancer.
design plants, animals and even babies with the characteristics we desire.
While such interventions, of course, pose ethical and regulatory considerations, the technology to make them happen has either already been developed or soon will be.
More precisely, this industrial revolution will likely have a significant positive impact on the global economy, simply by spurring economic growth.
pessimists might argue that we’re still living out the recession of the 2008 financial crisis, we’re really in the midst of a massive economic upswing brought on by the fourth industrial revolution.
with time, it will translate into real economic growth.
advanced technologies and digitization are making it cheaper to invest in renewable energy,
the increase in automation will bring prosperity, thereby increasing demand and creating new jobs and businesses.
digitization has enabled the private sector and individual citizens to easily
WikiLeaks is a great example. This relatively small enterprise successfully confronted an entire state.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations. But today, technologies develop at such incredible speed that regulations need to evolve far faster than before, and the rapid news cycle means leaders are under pressure to make fast decisions.
To respond to such constant changes, governments must collaborate with their citizens and private institutions in a brand new way. One example of this is investment in e-governance, which uses digital technology to increase citizen participation and the efficacy of government.
third industrial revolution is often referred to as either the computer revolution or the digital revolution.
currently experiencing a fourth industrial revolution, which began early in the twenty-first century.
the rise of machine learning and artificial intelligence.
material science to nanotechnology, energy to biology.
it merges these fields and connects them across digital, physical and biological platforms.
the modern world is more interconnected and richer in technology than ever before.
This change is driven by digitization and automation of production.
this revolution is defined by speed, but also by unprecedented returns to scale that allow businesses to produce the same or greater value with relatively fewer employment-associated costs. This change is driven by digitization and automation of production.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people. That’s just over a tenth of the workforce that the Detroit firms had in 1990.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The fourth industrial revolution has enabled a series of incredible new physical possibilities.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The
autonomous vehicles, 3D printing, advanced robotics and new materials.
because of advanced sensor technology, drones can now navigate much more effectively in response to the environment and therefore can be used for a number of new tasks, like dropping medicine into war zones
second physical trend of this industrial revolution is 3D printing, or, as it’s sometimes called, additive manufacturing.
3D printing is already being used in fields as diverse as medicine and energy production, producing everything from micro medical implants to massive wind turbines.
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat. But not every trend in the fourth
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat.
physical innovations are a major aspect of the fourth industrial revolution, others are purely digital.
IoT is a core concept that brings together physical and digital applications.
packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment,
Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
The current industrial revolution encompasses transformative digital and biological trends. While physical innovations are a major aspect of the fourth industrial revolution, others are purely digital. One of these is known as the internet of things, or IoT. The IoT is a core concept that brings together physical and digital applications. It describes a network between physical devices – be they smartphones or home appliances – and the people who use them. Constructing such a network is possible thanks to advances in technologies like transmitters and sensors. For example, these days packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment, enabling us to follow their progress as they make their way to us. Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
biological trends and innovations around things like genetics. Genetic engineering, in particular,
biological trends and innovations around things like genetics. Genetic engineering, in particular, will have a tremendous impact on humanity.
science may soon be capable of precision medicine. That is, scientists could do things like decode the genetic composition of a tumor and offer a treatment that’s tailored to that specific case of cancer.
design plants, animals and even babies with the characteristics we desire.
While such interventions, of course, pose ethical and regulatory considerations, the technology to make them happen has either already been developed or soon will be.
More precisely, this industrial revolution will likely have a significant positive impact on the global economy, simply by spurring economic growth.
pessimists might argue that we’re still living out the recession of the 2008 financial crisis, we’re really in the midst of a massive economic upswing brought on by the fourth industrial revolution.
with time, it will translate into real economic growth.
advanced technologies and digitization are making it cheaper to invest in renewable energy,
the increase in automation will bring prosperity, thereby increasing demand and creating new jobs and businesses.
digitization has enabled the private sector and individual citizens to easily
WikiLeaks is a great example. This relatively small enterprise successfully confronted an entire state.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations. But today, technologies develop at such incredible speed that regulations need to evolve far faster than before, and the rapid news cycle means leaders are under pressure to make fast decisions.
To respond to such constant changes, governments must collaborate with their citizens and private institutions in a brand new way. One example of this is investment in e-governance, which uses digital technology to increase citizen participation and the efficacy of government.
third industrial revolution is often referred to as either the computer revolution or the digital revolution.
currently experiencing a fourth industrial revolution, which began early in the twenty-first century.
the rise of machine learning and artificial intelligence.
material science to nanotechnology, energy to biology.
it merges these fields and connects them across digital, physical and biological platforms.
the modern world is more interconnected and richer in technology than ever before.
This change is driven by digitization and automation of production.
this revolution is defined by speed, but also by unprecedented returns to scale that allow businesses to produce the same or greater value with relatively fewer employment-associated costs. This change is driven by digitization and automation of production.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people.
the three most successful businesses in Detroit in 1990 – when the city was still a hotbed of industry – had a $36 billion market capitalization, $250 billion in revenue and employed 1.2 million people. By contrast, the three largest Silicon Valley companies in 2014 had revenue of $247 billion and market capitalization of over a trillion dollars but employed just 137,000 people. That’s just over a tenth of the workforce that the Detroit firms had in 1990.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The fourth industrial revolution has enabled a series of incredible new physical possibilities.
materials engineering and synthetic biology are now being fused in ways that could enable creating entirely new organs for people who need them. The
autonomous vehicles, 3D printing, advanced robotics and new materials.
because of advanced sensor technology, drones can now navigate much more effectively in response to the environment and therefore can be used for a number of new tasks, like dropping medicine into war zones
second physical trend of this industrial revolution is 3D printing, or, as it’s sometimes called, additive manufacturing.
3D printing is already being used in fields as diverse as medicine and energy production, producing everything from micro medical implants to massive wind turbines.
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat. But not every trend in the fourth
graphene, a newly discovered nanomaterial. It’s 200 times stronger than steel and a million times thinner than a single human hair. It’s also a very efficient conductor of both electricity and heat.
physical innovations are a major aspect of the fourth industrial revolution, others are purely digital.
IoT is a core concept that brings together physical and digital applications.
packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment,
Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
The current industrial revolution encompasses transformative digital and biological trends. While physical innovations are a major aspect of the fourth industrial revolution, others are purely digital. One of these is known as the internet of things, or IoT. The IoT is a core concept that brings together physical and digital applications. It describes a network between physical devices – be they smartphones or home appliances – and the people who use them. Constructing such a network is possible thanks to advances in technologies like transmitters and sensors. For example, these days packages in the post are often equipped with a sensor, a transmitter or some other radio frequency identification equipment, enabling us to follow their progress as they make their way to us. Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
Uber and Airbnb present other examples. Through digital platforms, these businesses connect physical objects, namely cars and houses, with the people who need them.
biological trends and innovations around things like genetics. Genetic engineering, in particular,
biological trends and innovations around things like genetics. Genetic engineering, in particular, will have a tremendous impact on humanity.
science may soon be capable of precision medicine. That is, scientists could do things like decode the genetic composition of a tumor and offer a treatment that’s tailored to that specific case of cancer.
design plants, animals and even babies with the characteristics we desire.
While such interventions, of course, pose ethical and regulatory considerations, the technology to make them happen has either already been developed or soon will be.
More precisely, this industrial revolution will likely have a significant positive impact on the global economy, simply by spurring economic growth.
pessimists might argue that we’re still living out the recession of the 2008 financial crisis, we’re really in the midst of a massive economic upswing brought on by the fourth industrial revolution.
with time, it will translate into real economic growth.
advanced technologies and digitization are making it cheaper to invest in renewable energy,
the increase in automation will bring prosperity, thereby increasing demand and creating new jobs and businesses.
digitization has enabled the private sector and individual citizens to easily
WikiLeaks is a great example. This relatively small enterprise successfully confronted an entire state.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations.
governments could use an entirely top-down approach to regulation; they could take their time to create, revise and enforce all manner of industrial regulations. But today, technologies develop at such incredible speed that regulations need to evolve far faster than before, and the rapid news cycle means leaders are under pressure to make fast decisions.
To respond to such constant changes, governments must collaborate with their citizens and private institutions in a brand new way. One example of this is investment in e-governance, which uses digital technology to increase citizen participation and the efficacy of government.
